Adaptive Variable Design Algorithm for Improving Topology Optimization in Additive Manufacturing Guided Design

IF 2.1 Q2 ENGINEERING, MULTIDISCIPLINARY Inventions Pub Date : 2024-07-01 DOI:10.3390/inventions9040070
Abraham Vadillo Morillas, Jesús Meneses Alonso, Alejandro Bustos Caballero, Cristina Castejón Sisamón, A. Ceruti
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Abstract

CAD-CAE software companies have introduced numerous tools aimed at facilitating topology optimization through Finite Element Simulation, thereby enhancing accessibility for designers via user-friendly interfaces. However, the imposition of intricate constraint conditions or additional restrictions during calculations may introduce instability into the resultant outcomes. In this paper, an algorithm for updating the design variables called Adaptive Variable Design is proposed to keep the final design space volume of the optimized part consistently under the target value while giving the main algorithm multiple chances to update the optimization parameters and search for a valid design. This algorithm aims to produce results that are more conducive to manufacturability and potentially more straightforward in interpretation. A comparison between several commercial software packages and the proposed algorithm, implemented in MATLAB R2023a, is carried out to prove the robustness of the latter. By simulating identical parts under similar conditions, we seek to generate comparable results and underscore the advantages stemming from the adoption and comprehension of the proposed topology optimization methodology. Our findings reveal that the integrated enhancements within MATLAB pertaining to the topology optimization process yield favourable outcomes with respect to discretization and the manufacturability of the resultant geometries. Furthermore, we assert that the methodology evaluated within MATLAB holds promise for potential integration into commercial packages, thereby enhancing the efficiency of topology optimization processes.
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自适应变量设计算法用于改进增材制造导向设计中的拓扑优化
CAD-CAE 软件公司推出了许多工具,旨在通过有限元模拟促进拓扑优化,从而通过友好的用户界面提高设计人员的使用便利性。然而,在计算过程中施加复杂的约束条件或附加限制可能会给计算结果带来不稳定性。本文提出了一种名为 "自适应变量设计 "的设计变量更新算法,以保持优化部件的最终设计空间体积始终低于目标值,同时为主算法提供多次更新优化参数和搜索有效设计的机会。这种算法旨在产生更有利于制造的结果,而且在解释上可能更直接。我们对几个商业软件包和在 MATLAB R2023a 中实施的拟议算法进行了比较,以证明后者的鲁棒性。通过在类似条件下对相同部件进行仿真,我们试图得出可比较的结果,并强调采用和理解所提出的拓扑优化方法所带来的优势。我们的研究结果表明,MATLAB 中与拓扑优化过程有关的集成增强功能在离散化和结果几何形状的可制造性方面产生了有利的结果。此外,我们认为在 MATLAB 中评估的方法有望集成到商业软件包中,从而提高拓扑优化过程的效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Inventions
Inventions Engineering-Engineering (all)
CiteScore
4.80
自引率
11.80%
发文量
91
审稿时长
12 weeks
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